PEG-variant biomaterials as selectively adhesive protein templates: model surfaces for controlled cell adhesion and migration

Three-dimensional culture of differentiating marrow stromal osteoblasts in biomimetic poly(propylene fumarate-co-ethylene glycol)-based macroporous hydrogels

This study assesses the ability of biomimetic poly(propylene fumarate-co-ethylene glycol)-based hydrogels to sustain the differentiation of marrow stromal cells (MSCs) to the osteoblastic phenotype and to produce a mineralized matrix in vitro. Macroporous hydrogels based on poly(propylene fumarate-co-ethylene glycol) with and without covalently linked RGD cell-adhesive peptide were synthesized and seeded with rat MSCs suspended in media or in a type I collagen solution. Cells suspended in media were found to adhere to RGD-modified but not to unmodified hydrogels. Cells suspended in a collagen solution were entrapped after collagen gelation and proliferated independent of the peptide modification of the hydrogel. Hydrogel modification with RGD peptide was sufficient to allow for the adhesion and differentiation of MSCs to the osteoblastic phenotype in the presence of osteogenic culture supplements. MSCs seeded with a collagen gel onto RGD-modified macroporous hydrogels after 28 days of culture showed a significant increase in cell numbers, from 15,200 +/- 2,000 to 208,600 +/- 69,700 cells (p < 0.05). Moreover, significant calcium deposition was apparent after 28 days of culture in RGD-modified hydrogels for cells suspended in a collagen gel in comparison to cells suspended in media, 3.47 +/- 0.26 compared to 0.82 +/- 0.20 mg Ca(2+) per scaffold (p < 0.05). Confocal microscopy revealed that MSCs suspended in a collagen gel and cultured on RGD-modified hydrogels for 28 days were adhered to the surface of the hydrogel while MSCs suspended in a collagen gel and cultured on unmodified hydrogels were located within the pores of and not in direct contact with the hydrogel surface. The results demonstrate that these biomimetic hydrogels facilitate the adhesion and support the differentiation of MSCs to the osteoblastic phenotype in the presence of osteogenic culture media.

Interaction of soft condensed materials with living cells: phenotype/transcriptome correlations for the hydrophobic effect

The assessment of biomaterial compatibility relies heavily on the analysis of macroscopic cellular responses to material interaction. However, new technologies have become available that permit a more profound understanding of the molecular basis of cell-biomaterial interaction. Here, both conventional phenotypic and contemporary transcriptomic (DNA microarray-based) analysis techniques were combined to examine the interaction of cells with a homologous series of copolymer films that subtly vary in terms of surface hydrophobicity. More specifically, we used differing combinations of N-isopropylacrylamide, which is presently used as an adaptive cell culture substrate, and the more hydrophobic, yet structurally similar, monomer N-tert-butylacrylamide. We show here that even discrete modifications with respect to the physiochemistry of soft amorphous materials can lead to significant impacts on the phenotype of interacting cells. Furthermore, we have elucidated putative links between phenotypic responses to cell-biomaterial interaction and global gene expression profile alterations. This case study indicates that high-throughput analysis of gene expression not only can greatly refine our knowledge of cell-biomaterial interaction, but also can yield novel biomarkers for potential use in biocompatibility assessment.

Adhesion and migration of marrow-derived osteoblasts on injectable in situ crosslinkable poly(propylene fumarate-co-ethylene glycol)-based hydrogels with a covalently linked RGDS peptide

Marrow-derived osteoblasts were cultured on poly(propylene fumarate-co-ethylene glycol) (P(PF-co-EG)) based hydrogels modified in bulk with a covalently linked RGDS model peptide. A poly(ethylene glycol) spacer arm was utilized to covalently link the peptide to the hydrogel. Three P(PF-co-EG) block copolymers were synthesized with varying poly(ethylene glycol) block lengths relative to poly(ethylene glycol) spacer arm. A poly(ethylene glycol) block length of nominal molecular weight 2000 and spacer arm of nominal molecular weight 3400 were found to reduce nonspecific cell adhesion and show RGDS concentration dependent marrow-derived osteoblast adhesion. A concentration of 100 nmol/mL RGDS was sufficient to promote adhesion of 84 +/- 17% of the initial seeded marrow-derived osteoblasts compared with 9 +/- 1% for the unmodified hydrogel after 12 h. Cell spreading was quantified as a method for evaluating adhesivity of cells to the hydrogel. A megacolony migration assay was utilized to assess the migration characteristics of the marrow-derived osteoblasts on RGDS modified hydrogels. Marrow-stromal osteoblasts migration was greater on hydrogels modified with 100 nmol/mL linked RGDS when compared with hydrogels modified with 1000 nmol/mL linked RGDS, while proliferation was not affected. These P(PF-co-EG) hydrogels modified in the bulk with RGDS peptide are potential candidates as in situ forming scaffolds for bone tissue engineering applications.

Polymers derived from the amino acid L-tyrosine: polycarbonates, polyarylates and copolymers with poly(ethylene glycol)

The natural amino acid L-tyrosine is a major nutrient having a phenolic hydroxyl group. This feature makes it possible to use derivatives of tyrosine dipeptide as a motif to generate diphenolic monomers, which are important building blocks for the design of biodegradable polymers. Particularly useful monomers are desaminotyrosyl-tyrosine alkyl esters (abbreviated as DTR, where R stands for the specific alkyl ester used). Using this approach, a wide variety of polymers have been synthesized. Here, tyrosine-derived polycarbonates, polyarylates, and polyethers are reviewed with special emphasis on recent developments relating to cellular and in vivo responses, sterilization techniques, surface characterization, drug delivery, and processing and fabrication techniques. The commercial development of tyrosine-derived polycarbonates is most advanced, with one polymer, poly(DTE carbonate) (E=ethyl), being under review by the USA Federal Drug Administration.

Crosslinking characteristics of and cell adhesion to an injectable poly(propylene fumarate-co-ethylene glycol) hydrogel using a water-soluble crosslinking system

The crosslinking characteristics of an injectable poly(propylene fumarate-co-ethylene glycol) [P(PF-co-EG)]-based hydrogel were investigated. A water-soluble crosslinking system was used, consisting of poly(ethylene glycol) diacrylate (PEG-DA), ammonium persulfate (APS), and ascorbic acid (AA). The effects of PEG block length of the P(PF-co-EG), APS concentration, AA concentration, and PEG-DA concentration on equilibrium water content, sol fraction, onset of gelation, mechanical properties, and endothelial cell adhesion were studied. The equilibrium water content of the hydrogels ranged from 57.1 +/- 0.3 to 79.7 +/- 0.2% whereas the sol fraction ranged from 2.5 +/- 0.0 to 3.33 +/- 5.4%. The onset of gelation times varied from 1.1 +/- 0.1 to 4.3 +/- 0.2 min. For all hydrogel formulations, the tensile strength fell between 61.7 +/- 18.2 and 401.3 +/- 67.5 kPa and tensile moduli ranged from 0.4 +/- 0.0 to 3.3 +/- 0.3 MPa. Endothelial cells attached to the hydrogels in a range of 3.9 +/- 1.4 to 31.1 +/- 14.1% of cells seeded. These findings suggest that injectable poly(propylene fumarate-co-ethylene glycol) hydrogel formulations in conjunction with a novel water-soluble crosslinking system may be useful for in situ crosslinkable tissue-engineering applications.

Poly(D,L-lactic acid)-poly(ethylene glycol)-monomethyl ether diblock copolymers control adhesion and osteoblastic differentiation of marrow stromal cells

Biodegradable polymers, such as poly(lactic acid) (PLA) and poly(lactic-coglycolic acid) (PLGA), are attractive materials for tissue engineering because of their degradative and mechanical properties, which permit scaffolds to be tailored to the individual requirements of different tissues. Although these materials support tissue development, their chemical properties offer no control of cell adhesion or function because their surfaces become immediately masked by adsorbing serum proteins when the materials come into contact with body fluids. Furthermore, adhesion proteins undergo conformational changes and a decrease in bioactivity when adsorbed to hydrophobic materials, such as PLA. To overcome these limitations, we modified the properties of PLA by synthesizing a diblock copolymer with poly(ethylene glycol) (PEG), which is known to reduce the amount of adsorbed proteins and to modify their conformation. By altering the PEG content of these diblock copolymers we were able to control the adsorption of adhesion proteins and, because cell adhesion takes place only in the presence of serum proteins, to control cell adhesion and cell shape. Marrow stromal cell differentiation to the osteoblastic phenotype was strongly improved on PEG-PLA compared with PLA, PLGA and tissue culture polystyrene and led to a 2-fold increase in alkaline phosphatase activity and mineralization.

Rational design of cytophilic and cytophobic polyelectrolyte multilayer thin films

Nanostructured polyelectrolyte multilayer thin films electrostatically assembled alternately from such polymers as poly(allylamine hydrochloride) (PAH) and poly(acrylic acid) (PAA) were investigated for their in vitro cell interactions. Not surprisingly, NR6WT cells, a highly adhesive murine fibroblast cell line, attached to many different multilayer combinations tested. However, PAH/PAA multilayers constructed at pH deposition conditions of 2.0/2.0 were completely bioinert. Analogous cell interactions were observed with PAH/poly(methacrylic acid) (PAH/PMA), PAH/sulfonated poly(styrene) (PAH/SPS), and poly(diallyldimethylammonium chloride)/SPS (PDAC/SPS) systems, thereby suggesting a general trend in the fibroblasts' response to multilayers. Specifically, highly ionically stitched films attracted cells, whereas weakly ionically cross-linked multilayers, which swell substantially in physiological conditions to present richly hydrated surfaces, resisted fibroblast attachment. Thus, by manipulating the multilayer pH or ionic strength assembly conditions or both, which in turn dictate the molecular architecture of the thin films, one may powerfully direct a single multilayer combination to be either cell adhesive or cell resistant.

A comparative study of chemical derivatisation methods for spatially differentiated cell adhesion on 2-dimensional microfabricated polymeric matrices

This paper describes a study of surface derivatisation methods applied to two-dimensional polymer matrices microfabricated using the Pressure-Assisted Microsyringe (PAM) technique. A blend of polylactide and polycaprolactone was used as the matrix material, and surface chemistry techniques based on silanes and polyethyleneglycol (PEG) derivatives were employed to render the surface underlying the scaffold anti-adhesive whilst polylysine was covalently coupled to the surface of the polymer matrix to enhance cell adhesion. Prior to cell-adhesion tests, the surfaces and matrices were analysed using physico-chemical techniques, such as surface tension, surface potential and fluorescence. Adhesion of primary endothelial cells was evaluated using cell counting techniques. The results demonstrate that both PEGs and silanes are about 66% efficient at demarcating endothelial cell adhesion in short term experiments and that covalently-bound polylysine to the polymer matrix increases cell adhesion twofold with respect to the adsorbed polypeptide.

Synthesis and characterization of triblock copolymers of methoxy poly(ethylene glycol) and poly(propylene fumarate)

Amphiphilic block copolymers were synthesized by transesterification of hydrophilic methoxy poly(ethylene glycol) (mPEG) and hydrophobic poly(propylene fumarate) (PPF) and characterized. Four block copolymers were synthesized with a 2:1 mPEG:PPF molar ratio and mPEGs of molecular weights 570, 800, 1960, and 5190 and PPF of molecular weight 1570 as determined by NMR. The copolymers synthesized with mPEG of molecular weights 570 and 800 had 1.9 and 1.8 mPEG blocks per copolymer, respectively, as measured by NMR, representing an ABA-type block copolymer. The number of mPEG blocks of the copolymer decreased with increasing mPEG block length to as low as 1.5 mPEG blocks for copolymer synthesized with mPEG of molecular weight 5190. At a concentration range of 5-25 wt % in phosphate-buffered saline, copolymers synthesized with mPEG molecular weights of 570 and 800 possessed lower critical solution temperatures (LCST) between 40 and 45 degrees C and between 55 and 60 degrees C, respectively. Aqueous solutions of copolymer synthesized with mPEG 570 and 800 also experienced thermoreversible gelation. The sol-gel transition temperature was dependent on the sodium chloride concentration as well as the mPEG block length. The copolymer synthesized from mPEG 570 had a transition temperature between 40 and 20 degrees C with salt concentrations between 1 and 10 wt %, while the sol-gel transition temperatures of the copolymer synthesized from mPEG molecular weight 800 were higher in the range 75-30 degrees C with salt concentrations between 1 and 15 wt %. These novel thermoreversible copolymers are the first biodegradable copolymers with unsaturated double bonds along their macromolecular chain that can undergo both physical and chemical gelation and hold great promise for drug delivery and tissue engineering applications.

Improving biomaterial properties of collagen films by chemical modification

Films of bovine collagen were chemically modified with the goal of improving their biomaterial properties. The modified films were investigated with respect to their affinity to fibroblast and endothelial cells, as well as their antibacterial properties tested by adhesion of Staphylococcus aureus. Modifications that only change the net charge of collagen, such as acetylation, succinylation, and treatment with glutaraldehyde (all increase the negative charge), and amination with ethylenediamine (EDA), N,N-dimethyl-EDA (DMEDA), or butylamine (all increase the positive charge), did not dramatically alter the mammalian cell attachment to the film. In contrast, derivatization of collagen using methoxypoly(ethylene glycol) (PEG) diminished the attachment of fibroblasts by 98 +/- 1% and of endothelial cells by more than 99% compared to unmodified collagen. Moreover, the rate of growth of fibroblasts dropped by 97 +/- 1% and that of endothelial cells by 88 +/- 3% as a result of PEGylation of collagen. Adhesion of S. aureus cells also plummeted by 93 +/- 2% as a result of this PEGylation. With these antifouling properties, PEG-collagen may be a promising coating material for coronary stents. Subsequent derivatization of PEG-collagen with EDA or DMEDA abolished its mammalian cell-repelling ability, whereas bacterial cell repulsion was partially retained: for example, DMEDA-modified PEG-collagen exhibits up to a 5-fold lower bacterial adhesion than collagen. It is worth noting that a material that allows mammalian cell attachment but reduces bacterial adhesion could be useful as an implant or coating.

Tissue spreading on implantable substrates is a competitive outcome of cell-cell vs. cell-substratum adhesivity

While the interactions of cells with polymeric substrata are widely studied, the influence of cell-cell cohesiveness on tissue spreading has not been rigorously investigated. Here we demonstrate that the rate of tissue spreading over a two-dimensional substratum reflects a competition or "tug-of-war" between cell-cell and cell-substratum adhesions. We have generated both a "library" of structurally related copolymeric substrata varying in their adhesivity to cells and a library of genetically engineered cell populations varying only in cohesiveness. Cell-substratum adhesivity was varied through the poly(ethylene glycol) content of a series of copolymeric substrata, whereas cell-cell cohesiveness was varied through the expression of the homophilic cohesion molecules N- and R-cadherin by otherwise noncohesive L929 cells. In the key experiment, multicellular aggregates containing about 600 cells were allowed to spread onto copolymeric surfaces. We compared the spreading behavior of aggregates having different levels of cell-cell cohesiveness in a series of copolymeric substrata having different levels of cell-substratum adhesivity. In these experiments, cell-cell cohesiveness was measured by tissue surface tensiometry, and cell-substratum adhesivity was assessed by a distractive method. Tissue spreading was assayed by confocal microscopy as the rate of cell emigration from similar-sized, fluorescence-labeled, multicellular aggregates deposited on each of the substrata. We demonstrate that either decreasing substratum adhesivity or increasing cell-cell cohesiveness dramatically slowed the spreading rate of cell aggregates.